A configurable driver integrated circuit is disclosed having a plurality of input/output terminals for interfacing exterior of the integrated circuit. The integrated circuit includes a plurality of driver circuits, with each driver circuit including a transistor having a source and a drain, and each of the source and drain thereof connected to a dedicated and respective one of the input/output terminals and further includes a gate driver for driving a gate of the transistor, with supply inputs associated with a floating voltage domain, and each driver circuit also includes a level shift circuit for shifting the level of a logic signal from a fixed voltage domain to the floating voltage domain. A switching circuitry generates switching signals in a fixed voltage domain for controlling the operation of each of the driver circuits in accordance with a predetermined configuration defined by external circuit.
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1. A configurable driver integrated circuit, comprising:
a plurality of input/output terminals for interfacing exterior of the integrated circuit;
a plurality of driver circuits, each of the driver circuits including:
a transistor having a source and a drain, and each of the source and drain thereof connected to a dedicated and respective one of the input/output terminals,
a gate driver for driving a gate of the transistor,
the gate driver for each of the plurality of driver circuits having supply inputs, the supply inputs including a positive supply input and a negative supply input, and for at least one of the plurality of driver circuits, the gate driver associated therewith having the negative and positive supply inputs associated with a floating voltage domain and each of the negative and positive supply inputs connected to a respective one of the input/output terminals and the associated transistor associated with the floating voltage domain, and
a level shift circuit for shifting a level of an input logic signal from a fixed voltage domain to the floating voltage domain to drive an input of the gate driver in the floating voltage domain associated with the at least one of the plurality of driver circuits; and
logic circuitry for generating logic signals in the fixed voltage domain for driving inputs of the level shift circuit and controlling operation of each of the driver circuits in accordance with a predetermined configuration defined by external circuit components configuring the driver circuits in a predefined driver class to drive a load.
18. A wireless power transfer unit (PMU) for communicating with a power receiving unit (PRU) over a wireless connection, comprising:
a resonator structure for wirelessly interfacing with the PRU; and
a configurable driver for receiving the ac driving signal, including:
an oscillator for generating an ac driving signal;
a plurality of input/outputs for interfacing exterior of the configurable driver;
a plurality of driver circuits, each of the driver circuits including:
a transistor having a source and a drain, and each of the source and drain thereof connected to a dedicated and respective one of the input/outputs of the configurable driver,
a gate driver for driving a gate of the transistor,
the gate driver for each of the plurality of driver circuits having supply inputs, the supply inputs including a positive supply input and a negative supply input, and for at least one of the plurality of driver circuits, the gate driver associated therewith having the negative and positive supply inputs associated with a floating voltage domain and each of the negative and the positive supply inputs connected to a dedicated and respective one of the input/outputs of the configurable driver, and
a level shift circuit for shifting a level of an input logic signal from a fixed voltage domain to the floating voltage domain to drive an input of the gate driver in the floating voltage domain associated with the at least one of the plurality of driver circuits; and
logic circuitry for receiving the ac driving signal and generating logic signals in the fixed voltage domain for driving inputs of the level shift circuit and controlling operation of each of the plurality of driver circuits in accordance with a predetermined configuration defined by external circuit components associated with the resonator structure configuring the driver circuits in a predefined driver class to drive the resonator structure.
13. A wireless power transfer unit (PMU) for communicating with a power receiving unit (PRU) over a wireless connection, comprising:
power supply circuitry generating an ac driving signal;
a resonator structure for wirelessly interfacing with the PRU; and
a configurable driver for receiving the ac driving signal, including:
a plurality of input/outputs for interfacing exterior of the configurable driver;
a plurality of driver circuits, each of the driver circuits including:
a transistor having a source and a drain, and each of the source and drain thereof connected to a dedicated and respective one of the input/outputs of the configurable driver,
a gate driver for driving a gate of the transistor,
the gate driver for each of the plurality of driver circuits having supply inputs, the supply inputs including a positive supply input and a negative supply input, and for at least one of the plurality of driver circuits, the gate driver associated therewith having the negative and positive supply inputs associated with a floating voltage domain and each of the negative and positive supply inputs connected to a respective one of the input/outputs of the configurable driver and the associated transistor associated with the floating voltage domain, and
a level shift circuit for shifting a level of an input logic signal from a fixed voltage domain to the floating voltage domain to drive an input of the gate driver in the floating voltage domain associated with the at least one of the plurality of driver circuits; and
logic circuitry for receiving the ac driving signal and generating logic signals in the fixed voltage domain for driving inputs of the level shift circuit and controlling operation of each of the driver circuits in accordance with a predetermined configuration defined by external circuit components associated with the resonator structure configuring the driver circuits in a predefined driver class to drive the resonator structure.
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This application is a continuation of U.S. patent application Ser. No. 15/677,989, filed Aug. 15, 2017, entitled MULTI-MODE POWER TRAIN INTEGRATED CIRCUIT, now U.S. Pat. No. 10,122,349, issued on Nov. 6, 2018, the specification of which is incorporated by reference herein in its entirety.
This application relates in general to Wireless Power Transfer (WPT) systems.
Wireless charging, also known as Wireless Power Transfer (WPT), is a technology that enables a power source to transmit electromagnetic energy to an electrical load across a gap, without interconnecting cords. Two directions for WPT are radiative wireless charging, which transfers energy via, for example, radiating electromagnetic, ultrasound, or acoustic waves and non-radiative charging, which transfers energy via an oscillating electromagnetic field.
The operation of the WPT requires both a Power Transmitting Unit (PTU) and a Power Receiving Unit (PRU) interface with each other through respective transmit and receive coils. The PTU includes a power generating unit that generates a DC voltage and converted to an AC voltage for driving the transmit coil. The transmit coil is typically configured as part of an H-bridge driver. Multiple different types of drivers can be utilized for realizing this H-bridge driver, such as Class D and Class E amplifiers.
In one aspect of the present invention, a configurable driver integrated circuit is disclosed having a plurality of input/output terminals for interfacing exterior of the integrated circuit. The integrated circuit includes a plurality of driver circuits, with each driver circuit including a transistor having a source and a drain, and each of the source and drain thereof connected to a dedicated and respective one of the input/output terminals. Each driver circuit further includes a gate driver for driving a gate of the transistor, and having supply inputs associated with a floating voltage domain, and each driver circuit also includes a level shift circuit for shifting the level of a logic signal from a fixed voltage domain to the floating voltage domain. A switching circuitry is provided for generating switching signals in a fixed voltage domain for controlling the operation of each of the driver circuits in accordance with a predetermined configuration defined by external circuit components configuring the driver circuits in a predefined driver class to drive a reactive load.
For a more complete understanding, reference is now made to the following description taken in conjunction with the accompanying Drawings in which:
Referring now to the drawings, wherein like reference numbers are used herein to designate like elements throughout, the various views and embodiments of Multi-Mode Power Train Integrated Circuit are illustrated and described, and other possible embodiments are described. The figures are not necessarily drawn to scale, and in some instances the drawings have been exaggerated and/or simplified in places for illustrative purposes only. One of ordinary skill in the art will appreciate the many possible applications and variations based on the following examples of possible embodiments.
Referring now to
The PTU 102 includes a primary resonator 106 that generates an oscillating magnetic field to wirelessly transmit power to the PRU 104. A matching circuit 108 is provided for interfacing between a power amplifier 110 and the primary resonator 106 through a driver 105. A power supply 112 is provided for generating power from an external source for input to the power amplifier 110. A controller 114 is provided for controlling the power supply 112, the power amplifier 110, and the matching circuit 108 and the primary resonator 106. The controller 114 interfaces with a communication module 116 in order to communicate with the PRU 104 over a bidirectional signaling path 118.
The PRU 104 includes a secondary resonator 120 interfacing with the primary resonator 106 of the PTU 102 via a wireless power path 122. The output of the secondary resonator 120 is input to a rectifier 124 for rectifying the output to a DC level, which is then input to a DC-to-DC converter 126. This comprises the output power which is then input to a device load 128. It should be understood that multiple loads could be interfaced with the DC-to-DC converter 126. A communication module 130 is operable to interface with the PTU 102 and the communication module 116 associated therewith via the signaling path 118. A controller 134 is provided on the PRU 104 for interfacing with the secondary resonator 120, the rectifier 124, the communication module 130 and the DC-to-DC converter 126.
The communication modules 116 and 130 provide for feedback signaling between the PRU 104 and the PTU 102 for the purpose of controlling the charging operation. The wireless power is generated at approximately 6.78 MHz of the Industrial Scientific Medical (ISM) frequency band. The communication on the signaling path 118 can be facilitated, for example, over an out-of-band communication path for control signaling and operates at the 2.4 GHz ISM band. For example, this out-of-band communication path can be via Bluetooth (BLE), Wifi, or radio.
The PTU 102 can operate in multiple functional states. One functional state is the Configuration state in which the PTU 102 does a self-check, one is the PTU Power Save state, in which the PTU 102 periodically detects changes in impedance at the primary resonator and one is the PTU Low Power state, in which the PTU 102 establishes a data connection with PRU(s). Another state is the PTU Power Transfer state, in which the PTU 102 can regulate power transfer. Another is the Local Fault State, which happens when the PTU 102 experiences any local fault conditions such as over-temperature. Another is the PTU Latching Fault state, which happens when rogue objects are detected, or when a system error or other failures are reported.
The PRU 104 also has a number of functional states. One is the Null State, when the PRU 104 is under-voltage, one is the PRU Boot state, when the PRU 104 establishes a communication link with the PTU 102, one is the PRU On state, when communication is performed, one is the PRU System Error State, when there is an over-voltage, over-current, or over-temperature alert, or when there is an error that has to shut down the power.
An exemplary communication protocol, used to support wireless charging functionality, can be via a Bluetooth Low Energy (BLE) link for the control of power levels, identification of valid loads, and protection of non-compliant devices. There can be three steps in the communication protocol, the first being device detection, the second being information exchange, and the third being charging control. With respect to device detection, the PTU 102 can beacon power until a PRU 104 broadcasts advertisements. The PTU 102 can reply to the PRU advertisements with a connection request. The information exchange allows the PTU 102 and PRU 104 to exchange their static and dynamic parameters. The charging control is initiated when the PTU 102 can provide sufficient power to meet the demand requested from the PRU 104, or when the PRU 104 is authorized to receive energy.
Referring now to
There are provided two symmetrical driver circuits. The first driver circuit is comprised of a gate driver 230 having the input thereof connected to the output of the oscillator 218 through a level shift/delay circuit 232 and the output thereof connected to a node 234. The node 234 drives the gate of an NFET 236 and to the gate of a PFET 238. The drain of the PFET 238 is connected to a boost output node 240, and the source thereof connected to a source node 242. The NFET 236 has the drain thereof connected to a drain node 244 and the source thereof connected to a source node 246. These nodes 240, 242, 244, and 246 are external nodes to the IC 202. Additionally, the gate driver 230 has the power supply input on a node 248 connected to a node 250, which is connected to the boost node 240 and the ground or VSS node on a line 249 connected to the source node 246. The node 250 is connected to the cathode of a diode 252, the anode thereof connected to the output of an Under Voltage Lockout (UVLO) and voltage reference circuit 254 that generates voltage references. The voltage reference generator 254 also provides references for the comparator 216. This voltage output to the anode of the diode 252 will typically be a voltage close to VDD at a voltage of approximately 5.0 V, as an example.
The second driver circuit is comprised of a gate driver 260 having the input thereof connected to the output of the oscillator 218 through a level shift/delay circuit 262 and the output thereof connected to a node 264. The node 264 drives the gate of an NFET 266 and the gate of a PFET 268. The drain of the PFET 268 is connected to a boost output node 270 and the source thereof connected to a source node 272. The NFET 236 has the drain thereof connected to a drain node 274 and the source thereof connected to a source node 276. These nodes 270, 272, 274, and 276 are external nodes to the IC 202. Additionally, the gate driver 260 has the power supply input on a node 278 connected to a node 280, which is connected to the boost node 270 and the ground or VSS node on a line 279 connected to the source node 276. The node 280 is connected to the cathode of a diode 282, the anode thereof connected to the output of the UVLO-reference circuit 254.
It is noted that both of the first and second drivers are configured such that, first, they are symmetrical and, second, that they are galvanically isolated from the power supply, i.e., they are basically operating on a floating power supply basis with the level shifters 232 and 262 shifting the voltage input thereto up from the voltage output by the oscillator and logic circuit 218.
There are provided a number of control inputs. There is provided an oscillator enable input 286 (OSC_EN) and two delay inputs 288 and 290, which two delay inputs 288 and 290 are input to control or define the delay in each of the level shift/delay surface 232 and 262, respectively.
Referring now to
There are provided two symmetrical driver circuits. The first driver circuit includes a first non-inverting driver 330 having the input thereof connected to the negative output of the logic circuit 318 and the output thereof connected to a node 331. The node 331 is connected through a first level shift/delay circuit 332 and the input of a second level shift/delay circuit 334. Each of the level shift/delay circuits 332 and 334 are controlled and interface to one of external delay nodes 388 and 390 to control the delay there through. The output of the first level shift/delay circuit 332 is provided to the input of a gate driver 336 and the output of the level shift/delay circuit 334 is provided to the input of the gate driver 338. Gate driver 336 drives the gate of an NFET 340 and the output of the gate driver 338 drives the gate of an NFET 342. The source of the NFET 340 is connected to a source node 344, which is also connected to the VSS of the gate driver 336 and the drain of NFET 340 is connected to a drain node 346. The source of the NFET 342 is connected to a source node 348, the drain thereof connected to a boost node 349. The VSS of driver 338 is also connected to the source node 348. The VDD input of the driver 336 is connected to a boost node 350 and the VDD input of the driver 338 is connected to a boost node 352. The boost node 352 and the VDD input to the driver 338 are connected to the cathode of a diode 353, the anode thereof connected to the output of a UVLO and reference voltage generator 354. The drain of the NFET 342 and the boost node 349 are connected to the cathode of a diode 355, the anode thereof connected to an output of the voltage reference generator 354.
It can be seen that both of the drivers 338 and 336, in addition to both of the NFET's 340 and 342, are galvanically isolated from the chip VDD and VSS. This will be described in more detail hereinbelow.
The first driver circuit includes a first non-inverting driver 360 having the input thereof connected to the negative output of the logic circuit 318 and the output thereof connected to a node 361. The node 361 is connected through a first level shift/delay circuit 362 and the input of a second level shift/delay circuit 364. Each of the level shift/delay circuits 362 and 364 are controlled and interface to one of external delay nodes 388 and 390 to control the delay therethrough. The output of the first level shift/delay circuit 362 is provided to the input of a gate driver 366 and the output of the level shift/delay circuit 364 is provided to the input of the gate driver 368. Gate driver 368 drives the gate of an NFET 370 and the output of the gate driver 368 drives the gate of an NFET 372. The source of the NFET 370 is connected to a source node 374, which is also connected to the VSS of the gate driver 366 and the drain of NFET 370 is connected to a drain node 376. The source of the NFET 372 is connected to a source node 378, the drain thereof connected to a boost node 379. The VSS of driver 368 is also connected to the source node 378. The VDD input of the driver 366 is connected to a boost node 386 and the VDD input of the driver 368 is connected to a boost node 382. The boost node 382 and the VDD input to the driver 366 are connected to the cathode of a diode 383, the anode thereof connected to the output of a UVLO and reference voltage generator 354. The drain of the NFET 372 and the boost node 379 are connected to the cathode of a diode 385, the anode thereof connected to an output of the voltage reference generator 384.
It can be seen that both of the drivers 368 and 366 in addition to both of the NFETs 370 and 372 are galvanically isolated from the chip VDD and VSS. This will be described in more detail hereinbelow.
Additionally, there is provided an oscillator enable input 386 (OSC_EN) and a High-side Enable control input 387. The oscillator enable input 386 is operable to enable the oscillator 318 to operate as an oscillator when a crystal is disposed across the nodes 322 and 320 of the IC 302. This will allow the oscillator to generate the positive and negative going signals. Thus, whenever the output of the oscillator is positive going, the driver 360 generates a positive pulse to turn on either of the transistors 372 and 370 and, whenever the oscillator is negative going, a pulse will be generated to drive the driver 330 to turn on either of the transistors 340 and 342. This will be described in more detail hereinbelow, but it will be appreciated that, whenever transistor 372 is on, transistor 370 will be off, and transistor 342 is off and transistor 340 is on to support full bridge operation, and the appropriate delays will be present during switching to prevent “shoot through” current. This provides for a standalone chip that generates a driving voltage. When the oscillator 318 is not enabled, the external signals are received on the VIN 2 and VIN1 nodes 306 and 308, respectively. This allows the external oscillator, which is a pulse width modulated signal, to generate a positive pulse on node 306 for the positive half of the cycle and a positive going pulse on the node 308 for the negative half of the cycle.
Referring now to
As noted hereinabove, both of the amplifiers 336 and 366 are galvanically isolated and, in this configuration, VSS for each of the amplifiers 336 and 366 are connected to ground by connecting the pins 344 and 374 to ground. Both of the VDD inputs to the amplifiers 336 and 366 are connected to VDD via the pins 350 and 386. This is an external VDD on a node 402, which also constitutes the external VDD input to the chip on node 310.
There are provided two external coils 406 and 408, with coil 406 being connected on one side to external VBUS voltage on a node 410, which can be a much higher voltage than VDD. One side of each of the coils 406 and 408 are connected to node 410. The other side of coil 406 is connected to pin 376 on the drain side of transistor 370, and the other side of the coil 408 is connected to pin 346 on the drain side of transistor 340. In this configuration, the oscillator in the block 318 is disabled via the pin 386 being connected to ground. The pin 376 is connected to a Vout + output node 412, and the pin 346 is connected to a Vout − output node 414. This comprises the two outputs of the bridge.
In operation, when VIN+ on pin 306 goes high, this causes transistor 370 to be turned on by pulling the gate thereof low which will pull node 410 low placing the full voltage on node 410 across the inductor 406. At the same time, transistor 340 is turned off, with the input on VIN − pin 308 being pulled low, turning off transistor 340, which will allow output node 414 to be pulled high by the inductor 408. The non-overlap delay logic is controlled such that the transistor 370 and 340 are not both turned on at the same time. Thus, transistor 370 is turned on at one time, pulling node 412 low, and transistor 340 is turned off allowing node 414 to be pulled high by the coil 408. Thereafter, transistor 370 is turned off and transistor 340 is turned on to pull node 414 low to energize the coil 408.
Referring now to
In operation, the amplifiers 336 and 366 are operable to control transistors 340 and 370, respectively, to pull their respective nodes 514 and 512 low. Thus, these two amplifiers 336 and 366 operate out of phase with respect to each other. This is also similar with respect to the amplifiers 338 and 368 and a respective transistors 342 and 372. Thus, the logic block 318 will operate to turn on transistor 372 and 340 when VIN+ on input pin 306 goes high and turn off transistors 370 and 340 when VIN− on input pin 308 goes low. When VIN− on input pin 308 goes high and VIN+ on input pin 306 goes low, transistor 342 and 370 are turned on.
When either of the amplifiers 368 and 338 turn on transistors 372 and 342, respectively, each of the transistors 372 and 342 will respectively pull respective nodes 512 and 514 high. Specifically, with respect to transistor 372, when transistor 372 turns on, pin 378 will be pulled up to the voltage on VBUS on node 410, pulling output node 512 high. Also, as the drain of transistor 372 is connected to node 410 via pin 379, the drain of transistor 342 is also connected to node 410 via pin 349. Since pin 378 is connected to pin 376, the drain of transistor 370, which is now off, will also be pulled high to the voltage on VBUS on node 410. When transistor 372 is turned off, and node 512 pulled low by transistor 370, the VSS supply for amplifier 368 and the source of transistor 372 will be pulled low by transistor 370. The diode 383 will maintain the voltage on the top side of external capacitor 520 at the reference supply output by voltage reference block 354, typically VDD. When the transistor 370 is turned off and transistor 372 turned on, node 378 will be pulled to the voltage of VBUS and the capacitor 520 will boost the voltage on node 382 and the VDD voltage for amplifier 368 supply voltage above the voltage on VBUS, maintaining a floating VDD. Thus, output node 512 is switched between the voltage on node 410, VBUS, and ground. The non-overlap delay logic block 318 controls the operation such that when node 512 is pulled high, node 514 is pulled low and, when node 512 is pulled low, node 514 is pulled high. The delay logic ensures that the transistors 370 and 340 are out of phase with the respective transistors 342 and 372 and non-overlapping, so as to remove any shoot-through current from the high side transistor to the low side transistor.
Since the two amplifiers 338 and the 368 are associated with a “floating” power supply via the respective external capacitor 518 and 520, the input to each of the amplifiers 338 and 368 for this particular configuration has to be level shifted to a voltage range between the voltage on VSS and VDD for each of the respective amplifiers 338 and 368. The respective level shift/delay blocks 334 and 364 facilitate this level shift. As noted hereinabove, each of the level shift/delay blocks 332, 334, 362 and 364 has a selectable delay associated there with via the pins 388 and 390. There are two delays available one for each of the two inputs, VIN+ and VIN−.
Referring now to
The NFET 602 has the source thereof connected to ground on the pin 344 and the drain thereof connected to a Vout− node 616. An external coil 618 is connected on one side thereof to the node 616 and on the other side thereof to the VBUS node 410, which is connected to an external supply which can be higher than VDD on a node 402. The external NFET 606 has the source thereof connected to ground and the pin 374 and the drain thereof connected to a Vout+ node 620. An external coil 622 is connected on one side thereof to the node 620 and on the other side thereof to the node 410 and the voltage on VBUS.
In operation, each of the amplifiers 336 and 366 and their respective transistors 340 and 370 operate similarly. With respect to the amplifier 336, when the input thereof is driven high the gate of transistor 340 is pulled high, pulling node 604 low, thus pulling the gate of NFET 602 low, turning off NFET 602. When node 604 is low, the lower plate of the capacitor 610 is also low and the upper plate thereof is charged via the diode 353 from the output of the voltage reference a block 354. When the NFET 602 is turned off, the coil 618 pulls the voltage on node 616 high. When the amplifier 336 changes state and turns off transistor 340 by pulling the gate thereof low, the gate of transistor 342 is raised high turning on the transistor 342. This will pull the node 348 up to the voltage on the node 349, which is VDD on node 402. When node 604 goes up to VDD, the voltage on the capacitor 610, it being a floating power supply, increases the voltage on the VDD supply input to the amplifier 338 to one VDD above VDD, or twice the supply voltage (assuming that the voltage on node 402 is VDD). This maintains the gate of the transistor 342 higher than the drain, thus maintaining conductance in the transistor 342, it being noted that the level shift/delay block 334 maintains the input to the amplifier 338 at a voltage above the voltage on node 348. This thus shifts the data input to a range between the voltage on node 348 and the voltage on node 349. The amplifiers 366 and 368 operate similarly to the amplifiers 336 and 338 except that they are out of phase therewith. Thus, when the input voltage VIN+ is high, the switching control signals will be configured by the logic block 318 to turn on transistor 606, the external NFET. This requires transistor 370 to be turned off and transistor 372 to be turned on. During that time, NFET 602 is turned off, and transistor 340 is turned on and transistor 342 is turned off. The appropriate delays and dead times are controlled by the logic block 318 in order to ensure that external NFETs 606 and 602 are not turned on at the same time nor are any of the pairs of transistors 340/342 or 370/372 turned on at the same time.
Referring now to
The amplifier 366 drives the gate of the transistor 370, the source thereof connected via the pin 374 to the output node 710 and the drain thereof is connected via the pin 376 to drive the gate of an external NFET 706 on a node 708. The VSS supply voltage of amplifier 366 is connected via pin 374 to the output voltage node 710 and the source of the transistor 370 is also connected output node 710. The VDD supply of amplifier 366 is connected via pin 386 to one side of an external capacitor 714, the other side thereof connected to the output node 710. The pin 386 is connected to the pin 379, which is connected to the cathode of the diode 385, which will conduct when the top side of the capacitor 714 is below the voltage on the anode of the diode 385.
The amplifier 368 has the VSS supply connected through the pin 378 to node 708 and the source of transistor 372 is connected to the node 708 through pin 378. The VDD supply of amplifier 368 is connected via pin 382 to one side of an external capacitor 720, the other side thereof connected to the node 708. The drain of transistor 372 is connected via node 379 to the top side of capacitor 714 and pin 386. Thus, amplifier 336 is associated with the non-floating power supply, whereas amplifiers 338, 366 and 368 are all associated with floating power supplies.
The external NFET 702 has the source thereof connected to ground and the drain thereof connected to a voltage output node 710. The NFET 706 has the source thereof connected to the node 710 and the drain thereof connected to the VBUS voltage on node 410.
In operation, external NFET 702 is controlled by amplifiers 336 and 338. The node 306 is associated with an input voltage VIN_HI, and the input pin 308 is associated with an input voltage VIN_LO. When the voltage on node 306 goes high, this will turn on external NFET 706 and turn off external NFET 702. To turn off external NFET 702, amplifier 336 pulls the gate of transistor 340 high turning on transistor 340, and amplifier 338 pulls the gate of transistor 342 low turning off transistor 342 to pull node 704 low. This will pull the node 348 to ground through transistors 340, and a node 352 will be pulled down to approximately VDD output supplied by the reference voltage block 354. The external NFET 706 is turned on by the amplifier 366 pulling the gate of transistor 370 low, and the amplifier 368 pulls the gate of transistor 372 high turning on transistor 372 to pull node 378 up to the voltage on node 379. Capacitors 714 and 720 will have a voltage across them of approximately VDD volts as supplied by the reference voltage block 354 via diodes 385 and 383, respectively assuming negligible drop across the diodes. Therefore, in this switched state, the output voltage Vout, node 710, is at the VBUS voltage because transistor 706 is turned on. The voltage at the gate node of transistor 706 is approximately VDD+VBUS because transistor 372 is turned on which connects the gate node of transistor 706 to the top plate of capacitor 714, while the bottom plate of capacitor 714 is connected to the source of external transistor 706 via node 710. At the same time, amplifier 368 applies a voltage of approximately 2*VDD+VBUS to the gate of transistor 372 allowing it to turn on since the supply voltage of amplifier 368 is connected to the top plate of external capacitor 720 which is a VDD voltage above the gate voltage of the external transistor 706 due to the stored VDD voltage across capacitor 720 from the previous state. This maintains transistor 372 in a conductive state, since the level shift delay block 364 maintains the logic state on the input to the amplifier 368 at a logic high.
When the voltage on the input pin 306 goes low and the voltage on the input pin 308 goes high, this turns off external NFET 706 and turns on external NFET 702. This requires amplifier 336 to turn off transistor 340, and amplifier 338 to turn one transistor 342, connecting the node 704 to the voltage VDD on the pin 349. To ensure that the amplifier 338 is in a fully operating state during this operation of turning on external NFET 702, the VDD supply is boosted up to a level of VDD above the voltage on the pin 348. Similarly, external NFET 706 is turned off by the amplifier 366 turning on transistor 370 and connecting the gate of external NFET 706 on node 708 to the output voltage pin 710. When the amplifier 368 turns off transistor 372, the voltage across the capacitor 720 will be the voltage between the node 710, which is ground, and the voltage on the cathode of diode 383. The voltage across the capacitor 714 will also be the voltage between the voltage on the node 710, which is ground, and the voltage on the cathode of the diode 385, allowing capacitors 714 and 720 to charge to approximately VDD volts.
Thus, it can be seen that this configuration for the half bridge Class D driver requires one of the amplifiers 336, 338, 366, and 368 to have its power supply voltage connected between ground and VDD and the other three amplifiers 338, 366, and 368 connected to floating power supplies.
Referring now to
In the operation of this device, the chip 302 requires nothing more than external configuration of the pins, a crystal and two coils 406 and 408 to function as a standalone free running PTU to charge an external device. In this operation, all that is required is for the device to be turned on via an external switch (not shown) which can connect VDD to the chip 302. The actual driving voltage to the coils 406 and 408 can be the voltage on the VBUS at node 410, which can be an external supply. With VDD to power the chip 302 and an external supply VBUS, a free running power generator is provided for generating wireless power. There is no feedback to regulate the power, however. A user will have to rely upon the actual external device itself and possibly any warning that might be generated by the comparator 316, noting that the device will have safety protection for over current and over temperature.
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The input on line 206/306 is input to the input of an inverting delay block 1504, the output of the inverting delay block 1504 input to the input of an inverter 1506, the output thereof input to an enable block 1508, and the output thereof input to one input of an OR gate 1510. The input on line 208/308 is input to the input of an inverting delay block 1512, the output of the inverting delay block 1512 input to an input of an inverter 1514, the output thereof input to an enable block 1516, the output thereof input to one input of an OR gate 1518. The delay blocks 1512 and 1504 will be controlled by the two delay signals on the inputs 288/388 and 290/390, respectively. They can be set to an “equal” delay in the event that the delay for the non-overlap operation is set externally. The two enable blocks 1508 and 1516 are controlled by the enable signal when it is at a “low” logic state.
The oscillator 1502, when enabled, will generate a clock signal at the appropriate frequency. The output of the oscillator 1502 is input to a node 1520. The node 1520 is input to one input of an NAND gate 1522. The output of gate 1522 is input to the input of an inverter 1524, the output thereof input to a programmable delay block 1526 is an inverter. The output of delay block 1526 is input to the input of an enable block 1528, the output thereof connected to the other input of the OR gate 1510. The node 1520 is connected through an inverter 1530 to one input of a NAND gate 1532, the output thereof connected through an inverter 1534 to the input of a programmable delay block 1536, which is an inverter. The output of delay block 1536 is input to an enable block 1538, the output thereof connected to the other input of the OR gate 1518. The output of the delay block 1526 is connected to the other input of the NAND gate 1532 and the output of the delay block 1536 is connected to the other input of the NAND gate 1522. The enable blocks 1528 and 1538 are enabled when the enable input is at a logic “high.” The oscillator is also enabled in this mode.
A separate delay input 1540 is provided for controlling the two delay. Thus, when the oscillator is enabled, the outputs of the delay blocks 1526 and 1536 will be 180° out of phase. These delay blocks 1526 and 1536, as well as the delay blocks 1504 and 1512 are controlled to delay both the positive and negative edges, and delay blocks can be set up to separately control each of the edges of resulting clock pulse, if necessary. The enable blocks will, when disabled, output a logic “low” to the associated OR gate.
Referring back to the embodiments of
It will be appreciated by those skilled in the art having the benefit of this disclosure that this multi-mode power train integrated circuit provides a configurable chip having a plurality of gate drivers with galvanically isolated power supplies and driving transistors for being configured in various Class E and Class D configurations. It should be understood that the drawings and detailed description herein are to be regarded in an illustrative rather than a restrictive manner, and are not intended to be limiting to the particular forms and examples disclosed. On the contrary, included are any further modifications, changes, rearrangements, substitutions, alternatives, design choices, and embodiments apparent to those of ordinary skill in the art, without departing from the spirit and scope hereof, as defined by the following claims. Thus, it is intended that the following claims be interpreted to embrace all such further modifications, changes, rearrangements, substitutions, alternatives, design choices, and embodiments.
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